The metabolism of ribosomal proteins microinjected into the oocytes of Xenopus laevis

When the total proteins from Xenopus laevis 60 S ribosomal subunits (TP60) were 3H-labeled in vitro and injected back into X. laevis oocytes, most 3H-TP60 are integrated into the cytoplasmic 60 S subunits via the nucleus during 16 h of incubation. In the oocytes whose rRNA synthesis is inhibited, 3H-TP60 are rapidly degraded with a half-life of 2-3 h. This degradation ceased as soon as rRNA synthesis was resumed, suggesting that ribosomal proteins unassociated with nascent rRNA are unstable in the oocytes. The degradation of 3H-TP60 in the absence of RNA synthesis was inhibited by iodoacetamide, a cysteine protease inhibitor, resulting in the accumulation of 3H-TP60 in the nucleus reaching about a threefold concentration in the cytoplasm. Considering the results with enucleated oocytes, we suggest that the X. laevis nucleus has a limited capacity to accumulate ribosomal proteins in an active manner but that those ribosomal proteins accumulated in excess over rRNA synthesis are degraded by a cysteine protease in the nucleus. By contrast, ribosomal proteins from Escherichia coli only equilibrate between the nucleus and the cytoplasm and are degraded by serine protease(s) in the cytoplasm without being integrated in the form of ribosomes in the nucleus.     

Regulated replication of DNA microinjected into eggs of Xenopus laevis

Purified circular DNA of SV40 or polyoma virus has been injected into unfertilized eggs of Xenopus laevis. Injected DNA initiates and completes multiple rounds of semiconservative replication while observing cellular regulatory signals. Thus replication initiation of double-stranded templates is induced after the oocyte is matured in vitro by progesterone. Only one round of replication of injected DNA is observed in a single cell cycle. When protein synthesis is inhibited unreplicated molecules continue to initiate replication at an undiminished rate, but reinitiation on previously replicated molecules is completely and selectively abolished. The DNA sequence requirements for the replication of injected DNA have been investigated. A variety of procaryotic DNA molecules and circularized fragments of SV40 or polyoma DNA replicate, regardless of whether they contain the viral origin of DNA replication. These results suggest that a specialized DNA sequence is not essential for the initiation of semiconservative DNA replication in the Xenopus embryo, nor is a specialized sequence essential for the mechanism which prevents reinitiation on a molecule which has already replicated within a cell cycle. The possibility is discussed that viral origins of replication are not valid models for the eucaryotic chromosome but are adaptations for uncoupling viral replication from the mechanism which prevents reinitiation within a cell cycle.     

In vivo studies on the incorporation of microinjected acidic proteins of the large ribosomal subunit from Escherichia coli and artermia salina into oocyte ribosomes from Xenopus laevis.

Tritium-labeled acidic proteins from the large ribosomal subunit of Artermia salina or Escherichia coli were microinjected into the cytoplasm of stage IV/V oocytes from Xenopus laevis. eL12 from the large ribosomal subunit of A. salina but not L7/L12 or L7/L12--L10 from E. coli is specifically incorporated into 60S ribosomal subunits of oocytes. This incorporation is not significantly inhibited by actinomycin D. Incorporation of eL12 into the 60S subunits occurs in enucleated oocytes, suggesting that active ribosomal ribonucleic acid synthesis and ribosome assembly as well are not prerequired for this reaction. Apparently the incorporation proceeds via an exchange reaction between a free cytoplasmic pool of eL12 and ribosomal eL12.     

Persistence and replication of plasmid DNA microinjected into early embryos of Xenopus laevis

The persistence and replication of defined circular and linear plasmid DNA molecules microinjected into fertilized eggs of Xenopus laevis were analyzed. For all plasmids tested, a small fraction of microinjected circular molecules was replicated; however, the overall copy numbers of either free form I or form II molecules usually did not increase through blastulation. In contrast, extensive amplification of input DNA sequences was seen whenever the microinjected DNA was assembled into high molecular weight concatemers. Moreover, the appearance and subsequent replication of injected sequences in high molecular weight DNA were enhanced when linear (form III), rather than circular, molecules were microinjected. The injected form III DNA was rapidly converted into long linear concatemers. All possible orientations of monomeric molecules within the concatemers were observed although, on occasion, head-to-tail orientations were favored. Long linear concatemers were replicated very efficiently, irrespective of the sequence of the input DNA. Form I and form II DNA molecules were also formed in the embryo from microinjected form III DNA. A small fraction of these circular forms was replicated, although overall copy numbers did not increase significantly. Form III molecules that remained monomeric were not observed to be replicated at all within our limits of detection. In some batches of embryos, form I and form II DNA molecules were replicated to the extent that overall copy number increased. Even in these cases, however, the amplification of long linear concatemers of the input DNA sequences was more efficient.     

Differential compartmentalization of plasmid DNA microinjected into Xenopus laevis embryos relates to replication efficiency.

Circular plasmid DNA molecules and linear concatemers formed from the same plasmid exhibit strikingly different fates following microinjection into Xenopus laevis embryos. In this report, we prove quantitatively that only a minority of small, circular DNA molecules were replicated (mean = 14%) from fertilization through the blastula stage of development. At all concentrations tested, very few molecules (approximately 1%) underwent more than one round of DNA synthesis within these multiple cell cycles. In addition, unlike endogenous chromatin, the majority of circular templates became resistant to cleavage by micrococcal nuclease. The extent of nuclease resistance was similar for both replicated and unreplicated templates. Sequestration of circular molecules within a membranous compartment (pseudonucleus), rather than the formation of nucleosomes with abnormal size or spacing, apparently conferred the nuclease resistance. In contrast, most linearly concatenated DNA molecules (derived from end-to-end joining of microinjected monomeric plasmid DNA) underwent at least two rounds of DNA replication during this same period. Linear concatemers also exhibited micrococcal nuclease digestion patterns similar to those seen for endogenous chromatin yet, as judged by their failure to persist in later stages of embryogenesis, were likely to be replicated and maintained extrachromosomally. We propose, therefore, that template size and conformation determine the efficiency of replication of microinjected plasmid DNA by directing DNA to a particular compartment within the cell following injection. Template-dependent compartmentalization may result from differential localization within endogenous nuclei versus extranuclear compartments or from supramolecular assembly processes that depend on template configuration (e.g., association with nuclear matrix or nuclear envelope).     

Xenopus laevis oocyte as a model for the study of the cytoskeleton

At the beginning of diplotene, the oocyte of Xenopus laevis is a cell of about 10–20 microns destined to increase 10,000-fold its size when the oocyte becomes filled with yolk platelets and has accumulated a great number of pigment granules in a half of its periphery. Its internal architecture is gradually accomplished during growth because of several factors, especially because of cytoskeletal changes. In the fully-grown oocyte, the cytoskeleton appears to sustain the eccentrically located germinal vesicle through arms radiating from the cortex to the germinal vesicle, a unique organization not to be found in other Amphibians. In this report, we summarized and analysed steps of cytoskeletal proteins and related mRNAs organization and function throughout diplotene stage, highlighting our studies in this animal model. The cytoskeletal proteins appear to exploit their activity with respect to ribosomal 60S subunit maturation and during translation. Most importantly, the polarity of the oocyte is achieved through a sophisticated and highly organized localization of mRNAs and cytoskeletal proteins in one side of the cell. This asymmetry will start the construction of the oocyte polarity that is instrumental for determining the characteristic of this cell, which will become an embryo. Moreover, in the same time membrane composition, conditioned by the underlying cytoskeletal organization, will acquire the prerequisites for sperm binding and fusion.     

Structural studies on site-directed mutants of domain 3 of Xenopus laevis oocyte 5 S ribosomal RNA

Base substitutions have been introduced into the highly conserved sequences of loops D and E within domain 3 of Xenopus laevis oocyte 5 S rRNA. The effects of these mutations on the solution structure of this 5 S rRNA have been studied by means of probing with nucleases, and with chemical reagents under native and semi-denaturing conditions. The data obtained with these mutants support the graphic model of Xenopus oocyte 5 S rRNA proposed by Westhof et al. In particular, our results rule out the existence of long-range base-pairing interactions between loop C and either loop D or loop E. The data also confirm that loops D and E in the wild-type 5 S RNA adopt unusual secondary structures and illustrate the importance of nucleotide sequence in the formation of intrinsic local loop conformations via non-canonical base-pairs and specific base-phosphate contacts. Consistent with this conclusion is our observation that the domain 3 fragment of Xenopus oocyte 5 S rRNA adopts the same conformation as the corresponding region in the full-length 5 S rRNA.     

Endogenous lactate transport in Xenopus laevis oocyte: dependence on cytoskeleton and regulation by protein kinases

Carbon flux in Xenopus laevis oocyte is glycogenic and an endogenous monocarboxylate transporter is responsible for intracellular lactate uptake. The aim of the present study was to determine if direct activation of protein kinases C and A modulates the activity of lactate transporter, as well as to investigate the possible role of cytoskeleton in these regulatory phenomena. The modulation was studied in isolated Xenopus oocytes of stage V–VI by measuring ¹⁴C-lactate uptake, both in the absence and in the presence of cytoskeletal-perturbing toxins. We found that the basal lactate transporter activity depends on the integrity of the cytoskeleton since it is partially inhibited by cytoskeleton disorganisation. Both PKA and PKC activation caused a significant decrease in transport activity and this decrease could be blocked by specific protein kinase inhibitors. The evidenced effects were not additive. Transport inhibition was annulled by agents that destabilize actin filaments or microtubules. We conclude that both protein kinases A and C, whose effects are mediated by cytoskeleton, negatively regulate the endogenous lactate transporter of Xenopus oocyte, suggesting that these kinases may have a role in the control of cytosolic pyruvate/lactate pool in the oocyte. All the experiments in this study comply with the current laws of Italy.     

Initiation of replication at specific origins in DNA molecules microinjected into unfertilized eggs of the frog Xenopus laevis

Initiation of DNA replication at specific origins was observed by electron microscopy after microinjection of pXlr11, pXlr14 or Col E1 plasmid DNA molecules into unfertilized eggs of the frog, Xenopus laevis. These results are in apparent contradiction with published reports (Harland and Laskey, Cell 21, 761-771, 1980; Laskey and Harland, Cell 24, 283-284, 1981) that specific origin sites were not used in Xenopus laevis eggs. We suggest that eucaryotic origins exist that both increase the probability of replication of contiguous sequences and determine the site at which replication is most likely to begin.     

Developmental change of a depolarization-induced sodium permeability in the oocyte of Xenopus laevis

In the full grown oocyte of Xenopus laevis, a sodium permeability can be induced by depolarization to positive potential with current injection. Voltage-clamp analysis has shown that depolarization causes a long-lasting modification of the membrane during which voltage-gated sodium channels become functional. In the present study, I have looked for the existence of these channels during cell growth. The channels appear during a very restricted period of cell growth, corresponding to Dumont stage V. A possible biological function is discussed.     

Preservation of Xenopus laevis rDNA-containing plasmid, pXlr101A, injected into the fertilized egg of Xenopus laevis

A circular rDNA-containing recombinant plasmid, pXlr101A, and its vector pBR322 were microinjected into the cytoplasm of fertilized Xenopus laevis eggs. The DNAs extracted from injected embryos at various stages of development were analyzed by hybridization with 32P-labeled pBR322 as the probe. Neither pXlr101A nor pBR322 were replicated, but they were maintained until the tailbud stage, disappearing during the muscular response stage. When pXlr101A-injected embryos were raised until the 2-week-old tadpole stage, sequences homologous to pBR322 were detectable in two Eco RI fragments of the pXlr101A-injected tadpole DNA. The sizes of the Eco RI fragments suggested that the plasmid sequences were preserved most probably in the chromosome-integrated form.     

Mouse interferon messenger RNA: characterization of the Xenopus laevis oocyte translation product

Mouse interferon messenger RNA was isolated from Newcastle disease virus-induced mouse Lpa cells and then translated in Xenopus laevis oocytes. The resulting oocyte homogenate containing translated interferon activity was unstable to treatment with 5 m urea and to repeated freeze/thaw cycles, and it was 1% cross-reactive on human cells, as was native mouse interferon. Both native mouse interferon and the mouse interferon produced by the translation of mouse interferon mRNA behaved almost similarly on CPG, poly(U)-Sepharose, and anti-mouse interferon antibody columns. When the oocyte-translated product was partially purified and analyzed on sodium dodecyl sulfate-polyacrylamide gels, it migrated as a major single band of activity at 21–22,000 daltons with a trailing edge at 22–30,000 daltons. Only minor activity was detected in the region of 35–40,000 daltons where the vast majority of the native mouse interferon migrated. Thus, the oocyte-translated mouse interferon product comigrated largely with the minor species of native mouse interferon with a little activity which corresponds with the larger molecular weight species of native mouse interferon.     

Isolation and characterization of a monosialosylgangliopentaosyl ceramide from Xenopus laevis oocyte.

A monosialosylgangliopentaosyl ceramide was isolated from Xenopus laevis oocytes. It represented 5.8% of the total acidic glycosphingolipids. From the results of sugar-composition analysis, enzymatic hydrolysis, permethylation analysis, and negative ion fast atom bombardment mass spectrometry, the structure of the ganglioside was determined to be as follows: [sequence: see text] The predominant species of fatty acids were alpha-hydroxy fatty acids, h22:0, h24:0, and h24:1. The long chain bases of this ganglioside consisted mainly of d18:1 sphingosine and phytosphingosine. Other acidic glycolipids were also characterized. The most abundant component of acidic glycolipids was sulfatide, which represented 85.7% of the total acidic glycolipid mixture. GM3, GM2, GM1a, and GD1a were also detected.     

Minor-class splicing occurs in the nucleus of the Xenopus oocyte

A small fraction of premessenger RNA introns in certain eukaryotes is excised by the minor spliceosome, which contains low-abundance small nuclear ribonucleoproteins (snRNPs). Recently, it was suggested that minor-class snRNPs are localized to and function in the cytoplasm of vertebrate cells. To test whether U12-type splicing occurs in the cytoplasm of Xenopus oocytes, we performed microinjections of the well-characterized P120 minor-class splicing substrate into the nucleus or into the cytoplasm. Our results demonstrate that accurate splicing of this U12-dependent intron occurs exclusively in the nuclear compartment of the oocyte, where U12 and U6atac snRNPs are primarily localized. We further demonstrate that splicing of both a major-class and a minor-class intron is inhibited after nuclear envelope breakdown during meiosis.